Edition |
First edition 2020. |
Description |
1 online resource (xv, 380 pages) : illustrations (chiefly color), maps (chiefly color) |
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text txt rdacontent |
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computer c rdamedia |
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online resource cr rdacarrier |
Series |
Developments in Earth surface processes ; v. 23 |
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Developments in earth surface processes ; 23.
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Bibliography |
Includes bibliographical references and index. |
Contents |
Intro -- Remote Sensing of Geomorphology -- Copyright -- Contents -- Contributors -- Foreword -- Reference -- Introduction to remote sensing of geomorphology -- Chapter 1: Structure from motion photogrammetric technique -- 1. Introduction -- 1.1. Brief historical summary and state of the art -- 1.2. Reasons for success in geomorphological surveys -- 2. Method -- 2.1. Choosing suitable settings to comply with the application at hand -- 2.1.1. Image quality -- 2.1.2. Ground sampling distance -- 2.1.3. Image network geometry -- 2.1.4. Camera parameter choice during bundle adjustment |
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2.1.5. Referencing: GCP weights and distribution -- 2.1.6. Exterior influences -- 2.2. Accuracy considerations in geomorphological applications -- 2.3. Direct geo-referencing (DG) for flexible UAV applications -- 2.3.1. Achievable accuracies -- 2.3.2. Guidelines for DG applications -- 3. Reconstructing processes across space -- 4. Reconstructing processes in time -- 4.1. Past and real-time reconstruction -- 4.2. Time-lapse imagery for 4D change detection -- 4.2.1. Guidelines for time-lapse SfM photogrammetry -- 5. Final remarks -- References -- Further reading |
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Chapter 2: Topo-bathymetric airborne LiDAR for fluvial-geomorphology analysis -- 1. High-resolution topography: Where is the bathymetry? -- 2. Synoptic fluvial bathymetry survey techniques -- 2.1. Topo-bathymetric lidar vs existing approaches -- 2.2. Topo-bathymetric airborne lidar sensors -- 2.3. Survey examples and typical data characteristics -- 3. Controls on depth penetration and surveyable rivers -- 3.1. Theoretical controls on the bathymetric waveform and bottom echo intensity -- 3.2. Results on maximum measurable depth and sensor comparison |
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3.3. Depth uncertainty and detail resolving capability -- 3.4. Surveyable rivers and survey strategy -- 4. Data processing -- 4.1. Water-surface detection, bathymetric classification, and refraction correction -- 4.2. FWF analysis -- 5. Applications in fluvial geomorphology -- 5.1. Multi-scale high-resolution fluvial geomorphology -- 5.2. Coupling with 2D-3D hydraulic modeling -- 5.3. Synoptic channel morphodynamics and sediment budget -- 6. Conclusions and remaining challenges -- 6.1. A priori prediction of depth penetration and river bathymetric cover |
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6.2. Automatic classification on massive lidar datasets -- 6.3. FWF analysis in the context of fluvial environments -- 6.4. Large-scale hydraulic modeling on topo-bathymetric data -- Acknowledgments -- References -- Chapter 3: Ground-based remote sensing of the shallow subsurface: Geophysical methods for environmental applications -- 1. Introduction -- 2. Methods -- 2.1. Geo-electrical (DC resistivity) methods -- 2.2. EMI methods and GPR -- 2.3. Seismics -- 3. Application examples -- 3.1. System structure -- 3.1.1. The Settolo site -- 3.1.2. The Trecate site -- 3.1.3. The Aviano site |
Subject |
Geomorphology -- Remote sensing.
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Landforms -- Remote sensing.
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Géomorphologie -- Télédétection.
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Relief (Géographie) -- Télédétection.
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Geomorphology -- Remote sensing
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Landforms -- Remote sensing
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Added Author |
Tarolli, Paolo.
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Mudd, Simon Marius.
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Other Form: |
Print version: 0444641777 9780444641779 (OCoLC)1057304424 |
ISBN |
9780444641786 (electronic bk.) |
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0444641785 (electronic bk.) |
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9780444641779 |
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0444641777 |
Standard No. |
AU@ 000067628816 |
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AU@ 000068133639 |
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UKMGB 019759679 |
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AU@ 000074353541 |
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